Development of an enhanced GFP-based dual-color reporter to facilitate genetic screens for the recovery of mutations in mice

Developmental fate and lineage commitment of singled mouse blastomeres

The inside-outside model has been invoked to explain cell-fate specification of the pre-implantation mammalian embryo. Here, we investigate whether cell-cell interaction can influence the fate specification of embryonic blastomeres by sequentially separating the blastomeres in two-cell stage mouse embryos and continuing separation after each cell division throughout pre-implantation development. This procedure eliminates information provided by cell-cell interaction and cell positioning. Gene expression profiles, polarity protein localization and functional tests of these separated blastomeres reveal that cell interactions, through cell position, influence the fate of the blastomere. Blastomeres, in the absence of cell contact and inner-outer positional information, have a unique pattern of gene expression that is characteristic of neither inner cell mass nor trophectoderm, but overall they have a tendency towards a 'trophectoderm-like' gene expression pattern and preferentially contribute to the trophectoderm lineage.

Inactivation of the putative tetracycline resistance gene HP1165 in Helicobacter pylori led to loss of inducible tetracycline resistance

Tetracycline has been used with other antibiotics in treatment of Helicobacter pylori infection. However, tetracycline resistance has developed in H. pylori clinical isolates, rendering treatment failure. Mutations in 16S rRNA genes have been reported to mediate tetracycline resistance in some isolates. The diversity of tetracycline resistance cases suggests multiple genes are involved. HP1165, a putative tetracycline resistance gene in H. pylori 26695, displays 49.8% identity to the tetracycline efflux gene tetA (P) from Clostridium perfringens. To determine the function of the HP1165 gene in H. pylori, the tetracycline resistance phenotype was investigated, transcription of HP1165 was examined by RT-PCR, and a DeltaHP1165 mutant was generated by insertion of the pBCalpha3 plasmid. The results showed that strains harboring HP1165 were induced to intermediate level resistance in the laboratory (minimum inhibitory concentration=4-6 microg/ml). No mutation was found at or near the tetracycline binding sites of the 16S rRNA gene. The gene was transcribed both in the induced tetracycline resistant and wild type strains, indicating translational or posttranslational control of gene function. Mutation of HP1165 gene resulted in increased tetracycline susceptibility and loss of inducible tetracycline resistance, suggesting that the HP1165 gene is involved in the inducible tetracycline resistance in H. pylori.

Gene-induced chondrogenesis of primary mesenchymal stem cells in vitro

Adult mesenchymal stem cells (MSCs) have the capacity to differentiate into various connective tissues such as cartilage and bone following stimulation with certain growth factors. However, less is known about the capacity of these cells to undergo chondrogenesis when these proteins are delivered via gene transfer. In this study, we investigated chondrogenesis of primary, bone marrow-derived MSCs in aggregate cultures following genetic modification with adenoviral vectors encoding chondrogenic growth factors. We found that adenoviral-mediated expression of TGF-beta1 and BMP-2, but not IGF-1, induced chondrogenesis of MSCs as evidenced by toluidine blue metachromasia and immunohistochemical detection of type II collagen. Chondrogenesis correlated with the level and duration of expressed protein and was strongest in aggregates expressing 10-100 ng/ml transgene product. Transgene expression in all aggregates was highly transient, showing a marked decrease after 7 days. Chondrogenesis was inhibited in aggregates modified to express >100 ng/ml TGF-beta1 or BMP-2; however, this was found to be partly due to the inhibitory effect of exposure to high adenoviral loads. Our findings indicate that parameters such as these are important functional considerations for adapting gene transfer technologies to induce chondrogenesis of MSCs.

Mice with the enhanced green fluorescent protein gene knocked in to chromosome 11 exhibit normal transmission ratios

Meiotic recombination between homologous chromosomes can be suppressed within a chosen segment by a regional inversion. In mice, this feature can be engineered and conveniently used in genetic screens to maintain chemically induced mutations within the homologous chromosome. The efficiency of an inversion-based mutagenesis screen can be substantially enhanced provided that the inversion chromosome and its wild-type (WT) homologue are both visibly tagged by two different coat color markers. Dual tagging eliminates labor associated with molecular genotyping. Previously, we reported the generation of the In(11)10Brd strain of mice carrying K14-agouti tagging a 30-cM inversion between the Trp53 and Egfr loci on mouse chromosome 11. Since K14-agouti causes yellowing of ears and tails, the In(11)10Brd mice are easily distinguishable from their WT littermates. In this paper, we describe the construction of a second strain of mice that carry the enhanced green fluorescent protein (EGFP) transgene at the Egfr locus. The EGFP carriers are visually recognizable by emitting green fluorescent light upon UV illumination. We found that the EGFP function was transmitted from one generation to another with expected Mendelian frequencies, and no detrimental effects of EGFP expression were detected in hemizygous or homozygous animals. The EGFP mice together with the previously generated In(11)10Brd inversion carriers constitute a complete set of reagents required for initiation of a regional ENU mutagenesis screen to address functionally more than one-third of mouse chromosome 11.

Development of intestinal M cells

Intestinal epithelium contains several specialized cell types including M cells, which can be found in the follicle-associated epithelium (FAE) or occasionally on the villi. M cells are critical for sampling of intestinal flora and for transferring pathogens across the epithelial barrier for recognition by the immune system. Development of M cells on the villi (M(v)) is independent of the presence of lymphocytes, while development of the FAE and M cells within the FAE (M(f)) is dependent on B lymphocytes. Here, the concept is discussed that B cells are not required for induction of M(f) differentiation but are required for transition to and maintenance of the mature M(f) phenotype. Signaling pathways possibly involved in the B-cell-independent stages of M-cell development are also discussed.

Moving forward with chemical mutagenesis in the mouse

The study of genetic variation in mice offers a powerful experimental platform for understanding gene function. Complex trait analysis, gene-targeting and gene-trapping technologies, as well as insertional and chemical mutagenesis approaches are becoming increasingly sophisticated and provide a variety of options for cataloguing gene activities and interactions. In this review we discuss fundamental and practical concepts related to chemical mutagenesis and we highlight the growing list of strategies for performing mutagenesis screens in mice. Gene-driven and diverse types of phenotype-driven screens provide several options for the recovery of the invaluable variety of alleles generated by chemical mutagenesis. The unique advantages offered using chemical mutagenesis compare favourably to and complement the spectrum of approaches available for functional annotation of the mammalian genome.